Self-contained micromechanical ventilator

ABSTRACT

The portable ventilator of the present invention provides a hands-free ventilatory support device in critical care, emergency, and resource-limited environments. The portable ventilator utilizes ambient air and includes a two dual head compressor system to provide a consistent air supply to the patient. The ventilator device is battery operated and is capable of providing up to 60 minutes of care. In a preferred embodiment, the portable ventilator of the present invention also includes a pneumatic subsystem, a control subsystem, a power subsystem and an alarm subsystem. The portable ventilator of the preferred embodiment includes a dual head and single head compressor system that operates alternatively, to provide a consistent and continuous inhalation and exhalation cycle. A portable ventilator of a second preferred embodiment includes a sole dual-head compressor that operates to provide a consistent and continuous inhalation and exhalation cycle.

This application is a continuation-in-part of application Ser. No. 10/228,166, filed Aug. 26, 2002, and a continuation-in-part of application Ser. No. 10/787,522, filed Feb. 26, 2004.

BACKGROUND OF THE INVENTION

Immediate medical care can save the lives of countless accident victims and military personnel. In the emergency medical services arena, there has long been an emphasis on the golden hour during which a patient must receive definitive medical attention. However, definitive medical attention is often limited, because of the lack of necessary equipment. While state of the art medical equipment can be found in medical facilities, such is not the case in emergency situations or military applications. This is particularly true in the area of ventilators.

Inspiration-only ventilators are known and widely used in hospital settings as they provide useful breathing circuits while minimizing the amount of oxygen utilized in treating the patient.

Current ventilators are generally designed for stationary, medical facilities. They are heavy, cumbersome and ill suited for portable applications. Most ventilators utilize medical grade air or highly flammable, compressed canisters of oxygen for its oxygen sources. These tanks air/oxygen are heavy, cumbersome, and unsuitable for transport. Prior-art ventilators also require large power sources, making them even less suitable for quick, on-site use. Lastly, most known ventilators require operation by trained personnel in treatment environments, where additional equipment and resources are easily available.

For example, U.S. Pat. No. 5,664,563 to Schroeder et al disclose a computer controlled pneumatic ventilator system that includes a double venturi drive and a disposable breathing circuit. The double venturi drive provides quicker completion of the exhalation phase leading to an overall improved breathing circuit. The disposable breathing circuit allows the ventilator to be utilized by multiple patients without risk of contamination. This device utilizes canistered oxygen sources. This device also would be rendered inoperable under the conditions anticipated by the present invention.

Therefore, there is a need for portable ventilators that overcome the disadvantages of the existing stationary ventilators.

The following portable ventilators address some of the needs discussed above. U.S. Pat. Nos. 6,152,135, 5,881,722 and 5,868,133 to DeVries et al. discloses a portable ventilator device that utilizes ambient air through a filter and a compressor system. The compressor operates continuously to provide air only during inspiration. The DeVries et al devices are utilized in hospital settings and are intended to provide a patient with mobility when using the ventilator. Since these devices are not directed to on-site emergency use, they provide closed loop control, sophisticated valve systems and circuitry that would render them inoperable under the types of emergency conditions anticipated by the present invention.

The references cited above recognize the need for portable ventilators that provide a consistent breathing circuit. As is the case with most portable ventilators, these devices provide breathing circuits including valve systems and an oxygen source. However, these devices lack the means by which they can be quickly facilitated in emergency situations where there are no stationary sources of power. Secondly, most of these devices depend on canister-style oxygen sources, which are cumbersome, and lessen the ability of the ventilators to be truly portable. Thirdly, the prior art ventilators do not provide breathing circuits that can be continuously used in the absence of stationary power sources. These and other drawbacks are overcome by the present invention as will be discussed, below.

SUMMARY OF THE INVENTION

It is therefore an objective of this invention to provide a portable ventilator that provides short-term ventilatory support.

It is another objective of the present invention to provide a portable ventilator that includes a pneumatic subsystem, a power subsystem and a sensor subsystem.

It is another objective of the present invention to provide a portable ventilator wherein the pneumatic subsystem includes two dual head compressor for increased air output.

It is another objective of the present invention to provide a portable ventilator wherein the pneumatic subsystem includes an accumulator.

It is another objective of the present invention to provide a portable ventilator that is a disposable one-use device having an indefinite shelf life.

It is also another objective of the present invention to provide a portable ventilator that includes a pneumatic subsystem, a power subsystem, a control subsystem and an alarm subsystem.

It is another objective of the present invention to provide a portable ventilator wherein the pneumatic subsystem includes one dual head compressor for increased air output and a means for relieving air manifold pressure with a single head compressor, thereby eliminating the need for an accumulator.

It is another objective of the present invention to provide a portable ventilator wherein the power subsystem includes a battery source and a jack that allows the ventilator to access an external power source, where the battery or the external power source is used to power the pneumatic, control and alarm subsystems.

It is another objective of the present invention to provide a portable ventilator wherein the power subsystem also includes a power conditioning circuit to eliminate fluctuating voltages to the control subsystem.

It is also another objective of the present invention to provide a portable ventilator wherein the control subsystem includes a timing circuit and a relay switch to control the on-off cycle of the dual-head and single head compressors.

It is also another objective of the present invention to provide a portable ventilator wherein the alarm subsystem is capable of visually indicating repairable, non-repairable and patient based problems as well as an audible alarm.

It is also another objective of the present invention to provide a portable ventilator system including a pneumatic subsystem having only one dual-head compressor, power subsystem, a control subsystem and an alarm subsystem, that is connected to a patient breathing circuit.

It is another objective of the present invention to provide a portable ventilator wherein the power subsystem also includes a current limit device to regulate current allowed to recharge battery source and a buck/boost that accepts a range of voltages from the power source and outputs a pre-set constant voltage to the vent to the control subsystem.

It is also another objective of the present invention to provide a portable ventilator wherein the control subsystem includes a timing circuit and a relay switch to control the on-off cycle of a dual-head compressor.

It is also another objective of the present invention to provide a portable ventilator wherein the alarm subsystem is includes a temperature sensor, a patient error LED, a device/system error LED and a battery monitor LED capable of visually indicating power, system and patient based problems as well as an audible alarm.

It is another objective of the present invention to provide a portable ventilator that is a disposable one-use device or a refurbished device having an indefinite shelf life.

These and other objectives have been described in the detailed description provided below.

DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic of the portable ventilator, the pneumatic subsystem, the power subsystem and the sensor subsystem.

FIG. 2 is a schematic of the pneumatic subsystem shown in FIG. 1.

FIG. 3 is a schematic of the power subsystem shown in FIG. 1.

FIG. 4 is a schematic of the sensor subsystem shown in FIG. 1.

FIG. 5 is a drawing of the portable ventilator shown in FIG. 1.

FIG. 6 is a schematic of the portable ventilator, the pneumatic subsystem, the power subsystem, the control subsystem and the alarm subsystem.

FIG. 6 a is a drawing of the portable ventilator shown in FIG. 6.

FIG. 7 is a schematic of the pneumatic subsystem shown in FIG. 6.

FIG. 8 is a schematic of the power subsystem shown in FIG. 6.

FIG. 9 is a schematic of the control subsystem shown in FIG. 6.

FIG. 9 a is a graph of the dual head compressor on-off cycle.

FIG. 9 b is a graph of resistors and capacitor charging and discharging timing cycle.

FIG. 9 c is a graph of the output of the timing circuit.

FIG. 9 d is a graph of the higher power on-off cycle from the relay switch to the dual head compressor.

FIG. 9 e is a graph of the higher power on-off cycle from the relay switch to the single head compressor.

FIG. 10 is a schematic of the alarm subsystem shown in FIG. 6.

FIG. 11 is a drawing of a preferred embodiment of the portable ventilator including the pneumatic subsystem, the power subsystem, the control subsystem and the alarm subsystem.

FIG. 11(a) is a drawing of the portable ventilator shown in FIG. 11.

FIG. 12 is a schematic of a pneumatic subsystem shown in FIG. 11.

FIG. 12(a) is a schematic of the patient circuit that is part of the pneumatic subsystem shown in FIG. 12.

FIG. 13 is a schematic of the power subsystem shown in FIG. 11.

FIG. 14 is a schematic of the control subsystem shown in FIG. 11.

FIG. 14(a) is a graph of the dual-head compressor on-off cycle.

FIG. 14(b) is a graph of resistors and capacitor charging and discharging timing cycle.

FIG. 14(c) is a graph of the output of the timing circuit.

FIG. 14(d) is a graph of the higher power on-off cycle from the relay switch to the dual head compressor.

FIG. 14(e) is a graph of the higher power on-off cycle from the relay switch to the single head compressor.

FIG. 15 is a schematic of the alarm subsystem shown in FIG. 11.

DETAILED DESCRIPTION OF THE EMBODIMENTS

The present invention is a portable ventilator that provides short-term ventilatory support to one or more patients for the management of trauma or respiratory paralysis. As shown in FIG. 1, the portable ventilator V assures consistent tidal volume and respiratory rate and provides hands free operational capabilities. The portable ventilator V is a fully functional multi-mode device suited for field hospital or forward surgical units, where experienced personnel can utilize the multi-mode capabilities unique to this device. Portable ventilator V is also suitable for use by untrained personnel, and in particularly useful in resource-limited environments. Additionally, the portable ventilator V can be configured as a disposable one-use device that has an indefinite shelf life.

Also in FIG. 1, the portable ventilator V of the present invention includes a pneumatic subsystem N, a power subsystem P, and a sensor subsystem S. Each of these systems shall be described below.

The Pneumatic Subsystem:

As shown in FIG. 2, the pneumatic subsystem N includes two dual head air compressors 1 a and 1 b for increased air output. Ambient or NVC filtered air is drawn into the dual head compressors 1 a and 1 b and compressed. The compressed air exits 1 a and 1 b and enters into the accumulator tank 2. An accumulator tank 2 is connected to each of the compressors 1 a and 1 b to act as a pneumatic holding area for the combined outputs (4 in total) of compressors 1 a and 1 b. The accumulator tank 2 overcomes the inconsistent nature of the phasing of the pressure waves inherent with dual head air compressors and prevents compressors 1 a and 1 b outputs from canceling each other. The accumulator tank 2 is further connected to a connector system 3. Since the compressors 1 a and 1 b function as constant-flow rates over a wide range of physiologic pressures, the connector system 3 provides constant, total airflow through the accumulator 2 to the user, for a necessary period of time. The periods of time are controlled through a timing circuit T that is part of a logic board B.

The Logic Board:

The logic board B includes timing circuit T and is connected to the power subsystem P. Logic board B controls power to compressors 1 a and 1 b in order to turn 1 a and 1 b on and off. Duration of the on-time of compressors 1 a and 1 b determines the amount of air that is delivered to the user. The logic board B utilizes analog logic and does not require microprocessor control. The logic board B is also connected to the sensor subsystem S.

The Sensor Subsystem:

As shown in FIG. 3, the portable ventilator V includes a sensor subsystem S that provides critical care monitoring and support critically ill patients in the emergency situations. The sensor subsystem S includes an airflow sensor 4 that detects loss of connection of the portable ventilator V from the patient's face mask or endotracheal tube. The sensor subsystem S also includes an airway pressure sensor 5. The pressure sensor 5 provides the desirable function of detecting the end of a previous breath (inhaled) in the user, so that air delivery can be delayed until the completion of the previous breath. An airflow sensor 6 is used to detect the cessation of exhalation of the previous breath if the scheduled start time for the next breath is not completed. The sensor subsystem S may be located within the ventilator V or be exterior to ventilator V.

The Power Subsystem:

As shown in FIG. 4, the power subsystem P of the portable ventilator V include disposable or rechargeable batteries 7 that are capable of operating under high capacity, wide temperature ranges and are compatible with the pneumatic subsystem N and the sensor subsystem S. In a preferred embodiment, the portable ventilator V of the present invention utilizes conventional lead-acid rechargeable batteries 7. The batteries 7 must provide at least 30 to 60 minutes of operating time.

The Portable Ventilator:

As shown in FIG. 5, the pneumatic subsystem N is connected to the sensor subsystem S and the power subsystem P and enclosed within housing 8 of the portable ventilator V. Housing 8 includes an rigid frame structure 8 a that is made of either plastic or metals and capable of withstanding physical and mechanical pressures. Portable ventilator V includes an input port 8 b which allows rechargeable batteries 7 to be powered using an external power source or an AC power source. Alternatively, batteries 7 may include disposable type batteries.

Housing 8 also a recessed control panel 8 c. Control panel 8 c includes ports for providing air to the user through known means. The panel 8 c also includes a switch for selecting desired air flow rates, an on/off switch and can include a switch for recharging the batteries 7. The control panel 8 c is recessed to prevent damage to any instrumentation positioned thereon.

The portable ventilator V of the present invention implements controlled ventilation and assists control ventilation to a patient. Example 1 below shows functionality and performance of two portable ventilators V described above.

EXAMPLE 1

The Sekos 2 and 3 ventilators were tested. All tidal volumes, respiratory rates and other parameters were within ±10% of the settings existing on the ventilator V. PERFORMANCE PARAMETER SEKOS 2 SEKOS 3 APPROX. WEIGHT (lb0 12 <6 APPROX. SIZE (in.) 10.75 W × 9.75 D × 7 H 5.7 W × 11.5 D × 3.5 H PHYSICAL VOLUME (in³) 733 230 BATTERY TYPE/SIZE 3.4 Ah lead acid 1.3 Ah lead acid OPERATING LIFE (h) 1.5-3 0.3-1 COMPRESSORS 2 2 CONTROLLABLE I:E RATIO No No RESP. RATE 6-30 10 OR 20 ONLY ADJUSTMENT (bpm) TIDAL VOLUME (ml) 200-1200 300, 900, OR 1200 MAX MINUTE VOLUME 20 (NOT YET TESTED) 20 (NOT YET TESTED) (L/m) INSPIRATORY FLOW No No MEASUREMENT EXPIRATORY FLOW Yes Yes MEASUREMENT

The portable ventilators tested above, have been shown to be superior in performance to traditional “ambu-bags”. These and other portable ventilators having the features discussed above are within the scope of this invention.

The present invention includes a preferred embodiment as shown in FIG. 6. The portable ventilator V₂, as shown in FIG. 6 includes a pneumatic subsystem N₂, a power subsystem P₂, a control subsystem C₂ and an alarm subsystem A₂.

The portable ventilator V₂ as shown in FIG. 6(a) includes a hard shell housing 100 having an exterior surface 100 a and an interior surface 100 b.

The Pneumatic Subsystem N₂:

As shown in FIG. 7, the pneumatic subsystem N₂ includes at least one dual head air compressor 101 for increased air output and a single head compressor 102 for closing a flutter valve 103. The pneumatic subsystem N₂ is responsible for the inhalation and exhalation cycles of the portable ventilator V₂. During the inhalation cycle, ambient air, a, is drawn into the dual head compressor 101 through the air input port 104. Ambient air a may also be passed through an NBC filter NBC, to remove contaminants, before passing through air input port 104. Alternatively, a small adapter (not shown) may be connected to the air input port 104 to allow the ventilator V₂ to operate by drawing air, a, from a purified source (not pictured). Upon entering the portable ventilator V₂, ambient air a is divided into two air flow paths by y-shaped medical grade tubing 105. The tubing 105 may also be pre-manufactured plastic or metal. As is understood by one of ordinary skill in the art, tubing 105 includes all necessary fittings and attachments. Additionally, tubing 105 may be an integral part of an interior portion 100 b of the hard shell housing 100, shown in FIG. 6 a. Ambient air a enters the dual head compressor 101, from tubing 105, through dual-head compressor input ports 101 a and 101 b. Dual head compressor 101 compresses ambient air a. It is important to note that combination of using a dual head compressor 101 with a single head compressor 102 is critical to the portable ventilator V₂ of the preferred embodiment of this invention as disclosed in FIGS. 6 through 10. It is also important to note that multiple single head compressors in place of the dual head compressor 101, as disclosed in the preferred embodiment of FIGS. 6 through 10, are outside the scope of this present invention. This is because dual-head compressors provide for increased efficiency and smaller size. This factor is essential to the proper design and function of the portable ventilator V₂.

EXAMPLE 2

For an equivalent tidal volume output:

Dual Head Compressor: weight—14.2 oz, size—28.9 cubic inches.

2 Single Head Compressors: weight—20.4 oz, size—32.0 cubic inches.

Dual-head compressors draw in outside air and increase pressure within, to allow for the proper tidal volumes to be pushed through a small amount of space. Using the ideal gas law PV=nRT, where (P)=pressure, (V)=volume, (n)=number of molecules, (R)=gas law constant, and (T)=temperature, the values nRT must remain constant when dual head compressor 101 is operational. Thus, as necessitated by the proper operation of ventilator V₂, obtaining particular volumes (V) of air from the environment into a small, fixed volume of the ventilator V₂, requires that the pressure (P) of the air a must be increased to keep nRT the same. The increased pressure of air a forces the air a through the ventilator V₂ into the lungs of the patient H. This is due to the tendencies of fluids, here the compressed air a, to flow from the area of greater pressure of the ventilator V₂ to the area of lower pressure of the lungs of the patient H, thereby filling them.

As shown in FIG. 7, compressed air a exits the compressor 101 through compressor output ports 101 c and 101 d and into the air manifold 106. Air manifold 106 is manufactured from plastic or metal. Air manifold 106 may also be an integral part of the interior portion 100 b. As is understood by one of ordinary skill in the art, air manifold 106 includes all necessary fittings and attachments. A pressure sensor 107 is connected to the air manifold 106 to monitor the pressure of air a delivered to the patient H. The pressure sensor 107 gauges the air pressure of compressed air a within air manifold 106. When air a exceeds a known threshold, the dual head compressor 101 is stopped and the single head compressor 102 is started, and air is no longer delivered to the patient H, as discussed below. As shown in FIG. 7, the air manifold 106 is also connected to the flutter valve 103. Flutter valve 103 allows compressed air a to enter through input port 103 a and be delivered to the patient H through bi-directional port 103 b. When compressed air a is being delivered to the patient H through bi-directional port 103 b, exhale port 103 c remains closed. When the patient H exhales however, the input port 103 a is closed off, and exhale port 103 c is open to allow exhaled air to be removed from the portable ventilator V₂. The exhalation cycle is described below. Compressed air a, that is delivered to the patient H, passes through medical grade tubing 108, flutter valve 103 and further through medical grade tubing 109 that is connected to the patient H through valve port 110. It is important to note that tubing 108 is integral to air manifold 106, and is shown in FIG. 7 as a separate element for descriptive purposes. Medical grade tubings 108 and 109 may also be pre-manufactured plastic or metal. As is understood by one of ordinary skill in the art, tubings 108 and 109 include all necessary fittings and attachments. Tubings 108 and 109 may be integral to interior portion 100 b. A standard medical grade, patient endotracheal tube (not shown) or tubing to a respiratory mask (not shown) is connected between the portable ventilator V₂ and the patient H at patient valve port 110.

During the exhalation cycle, exhaled air a_(e) is returned from the patient H through the patient valve port 110, tubing 109 and the bi-directional port 103 b. The single head compressor 102 causes flutter valve 103 to close input port 103 a, thereby directing the exhaled air a_(e) into exhaust port 103 c. Exhaled air a_(e) passes from exhaust port 103 c into medical grade tubing 111. Tubing 111 may be premanufactured plastic or metal and may be integral to interior portion 100 b. As is understood by one of ordinary skill in the art, tubing 111 includes all necessary fittings and attachments. Tubing 111 includes a t-junction 111 a that directs the exhaled air a_(e) into a second pressure sensor 112. Second pressure sensor 112 verifies whether patient H is exhaling. In an alternate embodiment, t-junction 111 a and pressure sensor 112 can be replaced with an in-line flow sensor (not shown). The exhaled air a_(e) is directed to a patient exhale port 115, positioned on the ventilator housing 100. Prior to reaching the exhale port 115, the exhaled air a_(e) is directed through an in-line capnography chamber 113. The capnography chamber 113 is used to detect the presence of exhaled CO₂ in exhaled air a_(e). The exhaled air a_(e) travels from the capnography chamber 113 through medical grade tubing 114. Tubing 114 may be premanufactured plastic or metal and may be integral to interior portion 100 b. As is understood by one of ordinary skill in the art, tubing 114 includes all necessary fittings and attachments. An additional colorometric or chemical capnography sensor CS may be connected externally to portable ventilator V₂ at exhale port 115, to further monitor ventilation efficiency. As shown in FIG. 7, the single head compressor 102, is connected to the flutter valve 103 and the air manifold 106 through medical grade tubing 116. It is important to note that tubing 116 is integral to air manifold 106, and is shown in FIG. 7 as a separate element for descriptive purposes. Tubing 116 may be premanufactured plastic or metal and may be integral to interior portion 100 b. As is understood by one of ordinary skill in the art, tubing 116 includes all necessary fittings and attachments. The single head compressor 102 operates only when the dual-head compressor 101 is not running. The single-head compressor 102 is used in this manner to ensure that the flutter valve input port 103 a remains fully closed and the exhaust port 103 c to be fully open in the exhalation cycle. This alternating operation of the dual head compressor 101 and the single head compressor 102 allows for dead volumes of air located in air manifold 106 to be evacuated through tubing 116, medical grade tubing 117 and exhaust port 118, between the inhalation cycles. Tubing 117 may be premanufactured plastic or metal and may be integral to interior portion 100 b. As is understood by one of ordinary skill in the art, tubing 117 includes all necessary fittings and attachments. It is important to note that the single head compressor 102 functions to mechanically close flutter valve 103. This mechanism is preferred over electronically controlled valves, as they lead to pressure losses. This mechanism is preferred over other venting systems and pressure relief valves to reduce loss of inspiration air and pressure gradients. Secondly, use of the single head compressor 102 forcibly pulls air a out of air manifold 106, thereby allowing for the next inhalation cycle to begin unimpeded by dead air within air manifold 106. Thirdly, the single head compressor 102 provides a brief instance of negative pressure during the closure of input port 103 a that assists the patient H to exhale. In addition, the operation of this dual head compressor 101 and the single head compressor 102 precludes the use of the accumulator 2, as discussed in the embodiments of FIG. 1, above. In an alternate embodiment, single head compressor 102, tubing 117 and exhaust port 118 can be used to relieve pressure and/or heat buildup within the portable ventilator V₂. Exhaust port 118 also protects the portable ventilator V₂ from contamination in extreme environmental hazards, as well as contamination from water, dust, mud, etc.

It is important to note that the exhaust port 118 is positioned away from exhaust port 115 so as not to alter capnography measurements obtained from capnography sensors 113 and CS.

The Power Subsystem P₂:

The power subsystem P₂, as shown in FIG. 8, is discussed below. The power subsystem P₂ provides power to the portable ventilator V₂. The power subsystem P₂ includes a battery source 201 and a power jack 202 that accepts an external power source EP. A 12-14 volt rechargeable battery is preferred as the battery source 201. However, replaceable batteries may also be utilized. Power jack 202 is connected to electronic circuit 203 which is further connected to the battery source 201. The electronic circuit 203 accepts power from the external power source EP through the power jack 202 to regulate voltage necessary to recharge battery source 201 and/or bypass battery source 201. When an external power source EP is connected to the power jack 202, the by-pass from the electronic circuit 203 allows the portable ventilator V₂ to operate if battery 201 is missing, inoperational or recharging. Power is directed from either the battery 201 or the electronic circuit 203 into a power switch 204. When the power is turned on, it is directed from the power switch 204 to a voltage regulator circuit 205 that provides power for the subsystems within the ventilator V₂.

The power subsystem P₂ utilizes the voltage regulator circuit 205 to eliminate fluctuating voltages to the control subsystem C₂. For components in the control and alarm subsystems C₂ and A₂, respectively, that require a lower voltage, a second voltage regulator circuit 206 is utilized. Additionally, the power subsystem P₂ provides driving voltage through the control subsystem C₂ to the dual head compressor 101 and the single head compressor 102 of the pneumatic subsystem N₂.

The Control Subsystem C₂:

As discussed under the pneumatic subsystem N₂ above, the on-off cycle between dual head compressor 101 and single head compressor 102 is critical to the operation of the preferred embodiment as shown in FIG. 6. As shown in FIG. 9, the control subsystem C₂ includes a timing circuit 401 that is used to control a mechanical relay switch 402 that in turn determines the on/off cycle between dual head compressor 101 and the single head compressor 102. The relay is configured as an electronically controlled single-pole double-throw switch 402. In a preferred embodiment, timing circuit 401 is a “555” circuit. The relay switch 402 is in turn connected to the single head compressor 102 of the pneumatic subsystem N₂ through a relay switch bar 402 a and a first connector position 402 b. Relay switch 402 and relay switch bar 402 a are preferably mechanical. The relay switch 402 is also connected to the dual head compressor 101 through the switch bar 402 a and second connector position 402 c. The timing circuit 401 is connected to a relay control 402 d, that is used to move the relay switch bar 402 a between first connector position 402 b and second connector position 402 c, based upon a breath-timing cycle generated by the timing circuit. The breath-timing cycle is discussed below. The timing circuit 401 is also connected to a capacitor 403, a first resistor 404 and a second resistor 405. Second resistor 405 is in turn connected to the power subsystem P₂ The connection between the power subsystem P₂ and the pneumatic subsystem N₂ is not shown in FIG. 9.

The breath-timing cycle is defined by the respiratory rate and the tidal volume, the values for which have been selected in accordance with American Medical Association guidelines.

As shown in FIG. 9 a, t ₁ represents the desired on time of compressor 101, correlating to the inhalation time, and t₂ represents the desired off time of compressor 101, correlating to the exhalation time. The sum of the inhalation and exhalation times (t₁+t₂) is one complete breath-timing cycle.

The respiratory rate is the number of complete breath-timing cycles per minute. The tidal volume is determined by the amount of air delivered during the inspiration phase in one breath-timing cycle. Tidal volume is the product of the flow rate of the compressor 101 by the on time t₁ of compressor 101.

Therefore: t ₁ =TV/f  (1)

-   -   where TV=tidal volume, f=flow rate of compressor 101;         t ₁ +t ₂=60 seconds/RR  (2)     -   where RR=respiratory rate, the number of breaths per minute;         t ₂=60/RR−t ₁=60/RR−TV/f.  (3)

The values for t₁ and t₂ are thus determined by using the AMA's respiratory rate and tidal volume guidelines, as well as the flow rate of compressor 101. Diode 406 is used to allow the possibility that t₁ less than t₂.

As would be understood by one of ordinary skill in the art, the capacitor 403, first resistor 404 and second resistor 405 form a charging and discharging timing circuit. In the present invention, as shown in FIG. 9 b, the charge cycle duration is selected to be equal to the desired inhalation time t₁. The discharge timing cycle is selected to be equal to the determined exhalation time t₂. Thus: t ₁=0.693(r ₁ +r ₂)c ₁ and  (4) t ₂=0.693(r ₂)c ₁;  (5)

where r₁ is the value of the first resistor 404, r₂ is the value of the second resistor 405 and c₁ is the value of the capacitor 403.

Because the output of the charging and discharging circuit is indeterminate with respect to an on or off state of compressor 101, timing circuit 401 is utilized to establish a clear demarcation of on and off states, as shown in FIG. 9 c, triggered by the output of the charging and discharging circuit.

It is important to note that timing circuit 401 is not powerful enough to operate compressors 101 and 102 directly. Therefore, the relay 402 is used where the output of timing circuit 401, as shown in FIG. 9 c, is the control input to the relay 402. A resistor 407 is used to prevent an electrical short, when the output of timing circuit 401 is on.

As shown in FIG. 9 d, the output of the charging and discharging circuit from timing circuit 401 controls the relay 402 such that the on-cycle of circuit 401 causes the relay 402 to create a pathway to deliver a high power on-cycle to dual head compressor 101.

As shown in FIG. 9 e, the off-cycle of timing circuit 401 causes the relay 402 to create a pathway to single head compressor 102. The on-cycle of compressor 101 and off cycle of compressor 102 make up the on-off cycle discussed above.

It is also important to note that the timing characteristics, as shown in FIGS. 9 c and 9 d, must correspond to the desired timing characteristics in FIG. 9 a for the proper operation of portable ventilator V₂.

The Alarm Subsystem A₂:

As shown in FIG. 10, the alarm subsystem A₂ includes a light alarm suppression switch 501 connected to a repairable LED indicator 502, a non-repairable LED indicator 503 and a patient problem LED indicator 504. The LED indicators 502, 503 and 504 are configured to indicate repairable problems, non-repairable problems, and patient based problems, respectively, within the portable ventilator V₂. The LED indicators 502, 503 and 504 are positioned on the outer surface 100 a of hard shell 100 of portable ventilator V₂. The alarm suppression switch 501 is used to disengage LED alarms 502, 503 and 504 when necessary. An audible alarm suppression switch 505 connected to an audible alarm switch 506. The audible alarm switch 506 is positioned on the outer surface 100 a of hard shell 100. The audible alarm suppression switch 505 is used to disengage audible alarm 506 when necessary.

A low voltage detect circuit 507 is connected to the battery 201 and the power switch 205 of the power subsystem P₂ to indicate when voltage is too low. Low voltage detect circuit 507 is also connected to the light alarm suppression switch 501 and repairable LED indicator 502 to denote a repairable problem to the user U. The low voltage detect circuit 507 is also connected to the audible alarm suppression switch 505 and the audible alarm to indicate a sound-based alarm to the user U.

A missing pulse/device/component failure detect circuit 508 is connected to the control subsystem C₂. The missing pulse/device/component failure detect circuit 508 is also is also connected to the light alarm suppression switch 501 and non-repairable LED indicator 503 to denote a non-repairable problem to the user U, ie portable ventilator V₂ must be replaced. The missing pulse/device/component failure detect circuit 508 is also connected to the audible alarm suppression switch 505 and the audible alarm to indicate a sound-based alarm to the user U.

Carbon dioxide detect circuit 509 is connected to a carbon dioxide event counter 510 and a carbon dioxide event trigger 511. The circuit 509, counter 510 and trigger 511 is connected to the capnography sensor 113 of the pneumatic subsystem N₂ to indicate insignificant carbon dioxide concentrations in exhaled air a_(e). The carbon dioxide event trigger 511 is further connected to the light alarm suppression switch 501 and patient problem LED indicator 502 to denote a improper connection or patient distress to the user U. The circuit 509, counter 510 and trigger 511 are also connected to the audible alarm suppression switch 505 and the audible alarm to indicate a sound-based alarm to the user U.

An exhale airflow detect circuit 512 is connected to an exhale event counter 513 and an exhale event trigger 514. The exhale circuit 512, event counter 513 and event trigger 514 is connected to the pressure sensor 112 of the pneumatic subsystem N₂. The exhale event trigger 514 is further connected to the light alarm suppression switch 501 and patient problem LED indicator 502 to denote a improper connection or patient distress to the user U. The exhale circuit 512, event counter 513 and event trigger 514 are also connected to the audible alarm suppression switch 505 and the audible alarm to indicate a sound-based alarm to the user U.

An inspiration pressure detect circuit 515 is connected to an inspiration event counter 516 and inspiration event trigger 517 to generate an alarm response when the ambient air, a, pressure is too high or too low. The inspiration circuit 515 is connected to the pressure sensor 107 of the pneumatic subsystem N₂. The inspiration event trigger 517 is further connected to the light alarm suppression switch 501 and patient problem LED indicator 502 to denote a improper connection or patient distress to the user U. The inspiration pressure detect circuit 515, inspiration event counter 516 and inspiration event trigger 517 are also connected to the audible alarm suppression switch 505 and the audible alarm to indicate a sound-based alarm to the user U. This inspiration pressure detect circuit 515 can also cause the relay control switch 402 d to immediately switch from operating the dual head compressor 101 to operating the single head compressor 102 when a preset pressure threshold is exceeded, to prevent harm to patient H.

A preferred embodiment of the present invention is shown in FIG. 11. The portable ventilator V₃ as shown in FIG. 11 includes a pneumatic subsystem N₃, a power subsystem P₃ a control subsystem C₃, an alarm subsystem A₃ that is connected to a patient breathing circuit PB. The preferred embodiment of as shown in FIG. 11 includes one dual-head compressor.

The portable ventilator V₃ as shown in FIG. 11(a) includes a hard shell housing 1000 having an exterior surface 1000 a and an interior surface 1000 b.

The Pneumatic Subsystem N₃:

As shown in FIG. 12, the pneumatic subsystem N₃ includes at least one dual head air compressor 1001 for increased air output. The pneumatic subsystem N₃ is responsible for executing the inhalation and exhalation cycles of the portable ventilator V₃. During the inhalation cycle, ambient air, a, is drawn into the dual head compressor 1001 through the air input port 1002 a through an optional NBC filter NBC, to remove contaminants, and through an intake connector 1002 b. Intake connector 1002 b is designed with nubs around the port opening to prevent any accidental blocking of the inlet port. Additionally, purified air a_(p), obtained from an optional purified source (not shown), is delivered via purified air port 1002 c and flow tube 1002 d. Upon entering the portable ventilator V₃, ambient air a enters the manifold 1002 e and divided into two air flows 1002 f and 1002 g by y-shaped medical grade tubing m. If utilized, ambient air a is mixed with the purified air a_(p), in the manifold 1002 e. The tubing m may be pre-manufactured plastic or metal and incorporates all necessary fittings and attachments. Additionally, tubing m may be an integral part of an interior portion 1000 b of the hard shell housing 1000, shown in FIG. 11 a. Air a/a_(p) enters the dual head compressor 1001, from air flow paths 1002(f) and 1002(g) through dual-head compressor input ports 1001 a and 1001 b. Dual head compressor 1001 compresses air a/a_(p) (hereinafter referred to as a_(c)). Dual-head compressors draws in outside air and increase pressure within, to allow for the proper tidal volume to be pushed through a small amount of space. Using the ideal gas law PV=nRT, where (P)=pressure, (V)=volume, (n)=number of molecules, (R)=gas law constant, and (T)=temperature, the values nRT must remain constant when dual head compressor 1001 is operational. Thus, as necessitated by the proper operation of ventilator V₃, obtaining particular volumes (V) of air a_(c) from the environment into a small, fixed volume of the ventilator V₃, requires that the pressure (P) of the air must be increased to keep nRT the same. The increased pressure of air a_(c) forces the air a_(c) through the ventilator V₃ into the lungs of the patient H. This is due to the tendencies of fluids, here the compressed air a_(c), to flow from the area of greater pressure of the ventilator V₃ to the area of lower pressure of the lungs of the patient H, thereby filling them.

As shown in FIG. 12, compressed air a_(c) exits the compressor 1001 through compressor output ports 1001 c and 1001 d and into the air manifold 1003. Air manifold 1003 is manufactured from plastic or metal. Air manifold 1003 may also be an integral part of the interior portion 1000 b. As is understood by one of ordinary skill in the art, air manifold 1003 includes all necessary fittings and attachments. A pressure sensor 1004 is connected to the air manifold 1003 to monitor the pressure of air a_(c) delivered to the patient H. The pressure sensor 1004 gauges the air pressure of compressed air a_(c) within air manifold 1003. When air a_(c) exceeds a preset threshold, the dual head compressor 1001 air is no longer delivered to the patient H, as discussed below. The air manifold 1003 is connected to a flow path 1005 and an output port 1006 though which the compressed air a_(c) flows to the patient breathing circuit PB, as shown in FIG. 12 and FIG. 12(a). As shown in FIG. 12(a), the compressed air a_(c) enters respiratory tubing 1007 and a breathing valve (flutter valve) 1008 through breathing valve input 1008 a which then provides compressed air a_(c) a pathway for entering a breathing valve bi-directional port 1009. It is important to note that the airflow prior to the bi-directional port 1009 is only oriented in the direction of the patient circuit PB. The compressed air a_(c) then flows through respiratory tubing 1010 though an inline End-tidal CO2 (EtCO₂) detector 1012, respiratory tubing 1013 and is delivered to the patient H through bi-directional port 1014. When compressed air a_(c) is being delivered to the patient H through bi-directional port 1014, exhale port 1015 remains closed. When the patient H exhales, however, the breathing valve input port 1008 a is closed off, and exhale port 1015 is opened to allow exhaled air a_(c) to be removed from the portable ventilator V₃. The EtCO₂ detector 1012 is used to detect the presence of exhaled CO₂ in exhaled air a_(c). A second pressure sensor 1016, through manifold 1017, a pressure port 1017 a and tubing 1018 is used to monitor both the patient's H inhale and exhale pressures. The exhalation cycle is described below. As is understood by one of ordinary skill in the art, tubings m, 1005, 1007, 1010, 1013, and 1017 are premanufactured plastic or metal, may be integral to interior portion 1000 b and include all necessary fittings and attachments. A standard medical grade, patient endotracheal tube (not shown) or tubing to a respiratory mask (not shown) or LMA (not shown) is connected between the portable ventilator V₃ and the patient H at bi-directional port 1014.

During the exhalation cycle, exhaled air a_(e) is returned from the patient H through the bi-directional port 1014, tubing 1013 and the bi-directional port 1009. The dual-head compressor 1001 is powered off to allow valve 1008 to close input port 1008 a, thereby directing the exhaled air a_(e) into exhaust port 1015. Exhaled air a_(e) passes from the exhaust port 1015 and into the atmosphere.

The Power Subsystem P₃:

The power subsystem P₃, as shown in FIG. 13, is discussed below. The power subsystem P₃ provides power to the portable ventilator V₃. The power subsystem P₃ includes a battery source 2001 and a power jack 2002 that accepts an external power source EP. A 12-14 volt rechargeable battery is preferred as the battery source 2001. However, replaceable batteries may also be utilized. Power jack 2002 is connected to a current limit device 2003 which is further connected to the battery source 2001. The current limit device 2003 accepts power from the external power source EP through the power jack 2002 to regulate current allowed to recharge battery source 2001. When an external power source EP is connected to the power jack 2002, the by-pass from the current limit device 2003 allows the portable ventilator V₃ to operate if battery 2001 is missing, inoperational or recharging. Power is directed from either the battery 2001 or the current limit device 2003 into a power switch 2004. When the power is turned on, it is directed from the power switch 2004 to a buck/boost circuit 2005. The buck/boost circuit accepts a range of voltages from the power source and outputs a pre-set constant voltage. Additionally, the power switch is also connected to a voltage regulator circuit 2006 that provides a lower voltage for the subsystems within the ventilator V₃, specifically, the control and alarm subsystems C₃ and A₃, respectively.

The power subsystem P₃ utilizes the voltage regulator circuit 2006 to eliminate fluctuating voltages to the control subsystem C₃ and alarm subsystem A₃. Additionally, the power subsystem P₃ provides driving voltage through the control subsystem C₃ to the dual head compressor 1001 of the pneumatic subsystem N₃.

The Control Subsystem C₃:

As discussed under the pneumatic subsystem N₃ above, the on-off cycle (during inhalation and exhalation) of the dual head compressor 1001 is critical to the operation of the preferred embodiment as shown in FIG. 11. As shown in FIG. 14, the control subsystem C₃ includes a timing circuit 4001 that is used to control a mechanical relay switch 4002 that in turn determines the on/off cycle of the dual head compressor 1001. The relay is configured as an electronically controlled single-pole double-throw switch 4002. In a preferred embodiment, timing circuit 4001 is a “555” circuit. The relay switch 4002 includes a relay switch bar 4002 a and a first connector position 4002 b. Relay switch 4002 and relay switch bar 4002 a are preferably mechanical. The relay switch 4002 is also connected to the dual head compressor 1001 through the switch bar 4002 a and second connector position 4002 c. The timing circuit 4001 is connected to a relay control 4002 d, through a logic circuit 4003 that is used to move the relay switch bar 4002 a between first connector position 4002 b and second connector position 4002 c, based upon a breath-timing cycle generated by the timing circuit. The breath-timing cycle is discussed below. The logic circuit 4003 is also connected to a secondary breathing cycle switch 4004 and an alternative breathing cycle circuit 4005. Dependent upon need, a user may utilize switch 4004 to select a secondary breathing-timing cycle of breathing cycle circuit 4005. The timing circuit 4001 is also connected to a capacitor 4006, a first resistor 4007 and a second resistor 4009. Second resistor 4009 is in turn connected to the power subsystem P₃. The connection between the power subsystem P₃ and the pneumatic subsystem N₃ is not shown in FIG. 14.

The relay switch 4002 is in turn connected to current sensors 4011 and 4012 for determining the patient H's breathing state during the inhalation-exhalation cycle (where inhalation and exhalation cycle each have a corresponding on-off cycle) of the dual-head compressor 1001. When relay switch bar 4002 a is connected to the first connector position 4002 b, current sensor 4011 is utilized to verify the position of switch bar 4002 a. In this position, the ventilator should be in the exhale-cycle. Current sensor 4011 is also connected to alarm subsystem A₃, to alert a user to alarm conditions should threshold current values not be met. When relay switch bar 4002 a is connected to the second connector position 4002 c, current sensor 4012 is utilized to determine whether there is current to the dual-head compressor 1001 during the inhalation-cycle. Current sensor 4012 is also connected to alarm subsystem A₃ to alert a user to alarm conditions should threshold current values not be met Current sensor 4012, dual-head compressor 1001, and alarm subsystem A₃ are also connected to a safety cutoff circuit 4013. The safety cut off circuit 4013 can cut off power to the dual-head compressor 1001 should it receive a signal from the alarm subsystem A₃ that the patient or ventilator is in an alarm state. In at least one alarm state, the duel-head compressor 1001 is kept powered off to prevent any potential harm to patient H and/or to conserve enough battery 2001 energy to alarm the user that the patient H or ventilator V₃ needs immediate attention.

The breath-timing cycle is defined by the respiratory rate and the tidal volume.

As shown in FIG. 11 a, t ₁ represents the desired on time of compressor 1001, correlating to the inhalation time, and t₂ represents the desired off time of compressor 1001, correlating to the exhalation time. The sum of the inhalation and exhalation times (t₁+t₂) is one complete breath-timing cycle.

The respiratory rate is the number of complete breath-timing cycles per minute. The tidal volume is determined by the amount of air delivered during the inspiration phase in one breath-timing cycle. Tidal volume is the product of the flow rate of the compressor 1001 by the on time t₁ of compressor 1001.

Therefore: t ₁ =TV/f  (4)

-   -   where TV=tidal volume, f=flow rate of compressor 1001;         t ₁ +t ₂=60 seconds/RR  (5)     -   where RR=respiratory rate, the number of breaths per minute;         t ₂=60/RR−t ₁=60/RR−TV/f.  (6)

The values for t₁ and t₂ are thus determined by using the desired respiratory rate and tidal volume as guidelines, as well as the flow rate of compressor 1001. Diode 4008 is used to allow the possibility that t₁ is less than t₂.

As would be understood by one of ordinary skill in the art, the capacitor 4006, first resistor 4007 and second resistor 4009 form a charging and discharging timing circuit. In the present invention, as shown in FIG. 14 b, the charge cycle duration is selected to be equal to the desired inhalation time t₁. The discharge timing cycle is selected to be equal to the determined exhalation time t₂. Thus: t ₁=0.693 r ₁ c ₁ and  (7) t ₂=0.693(r ₂)c ₁;  (8)

where r₁ is the value of the first resistor 4007, r₂ is the value of the second resistor 4009 and c₁ is the value of the capacitor 4006.

Because the output of the charging and discharging circuit is indeterminate with respect to an on or off state of compressor 1001, timing circuit 4001 is utilized to establish a clear demarcation of on and off states, as shown in FIG. 14 c, triggered by the output of the charging and discharging circuit. The output of timing circuit 4001 is then an input to logic circuit 4003. If the secondary breathing cycle switch 4004 is not selected by the user, the output of logic circuit 4003 is a square wave with the same timing of the output of timing circuit 4001.

It is important to note that logic circuit 4003 output is not powerful enough to operate compressor 1001 directly. Therefore, the relay 4002 is used where the output of logic circuit 4003, as shown in FIG. 14 c, is the control input to the relay 4002. A resistor 4010 is used to prevent an electrical short, when the output of timing circuit 4001 is on.

As shown in FIG. 14 d, the output of the logic circuit 4003 controls the relay 4002 such that the on-cycle of circuit 4003 causes the relay 4002 to create a pathway to deliver a high power on-cycle current to dual head compressor 1001 for the inhalation state.

As shown in FIG. 14 e, the off-state cycle of logic circuit 4003 causes the relay 4002 to create a pathway to force the dual-head compressor 1001 into an off-state, thus creating the timing of the exhalation cycle. FIG. 14 e represents the output of current sensor 4011.

It is also important to note that the timing characteristics, as shown in FIGS. 14 c and 14 d, must correspond to the desired timing characteristics in FIG. 14 a for the proper operation of portable ventilator V₃.

The Alarm Subsystem A₃:

As shown in FIG. 15, the alarm subsystem A₃ includes a light suppression switch 5001 connected to a patient error LED indicator 5002, a device/system error LED indicator 5003, and battery monitor LEDs 5004. The LED indicators 5002, 5003 and 5004 are configured to indicate repairable patient-based problems, non-repairable device problems, and battery power, respectively, within the portable ventilator V₃. The LED indicators 5002, 5003 and 5004 are positioned on the outer surface 1000 a of hard shell 1000 of portable ventilator V₃. The light suppression switch 5001 is used to disengage LEDs 5002, 5003 and 5004 when necessary. An audible alarm suppression switch 5005 is connected to an audible alarm 5006. The audible alarm 5006 is positioned on the inner surface 1000 b of hard shell 1000, but could also easily be on the outer surface 1000 a. The audible alarm suppression switch 5005 is used to disengage audible alarm 5006 when necessary.

A low voltage detect circuit 5007 is connected to the battery 2001 and the power switch 2004 of the power subsystem P₃ to indicate when voltage is too low. Low voltage detect circuit 5007 is also connected to the light suppression switch 5001. The low voltage detect circuit 5007 is also connected to the audible alarm suppression switch 5005 and the audible alarm 5006 to indicate a sound-based alarm to the user.

A patient/system/battery failure detect circuit 5008 is connected to the control subsystem C₃. The patient/system/battery failure detect circuit 5008 is also connected to the light suppression switch 5001. The patient/device/battery failure detect circuit 5008 is also connected to the audible alarm suppression switch 5005 and the audible alarm 5006 to indicate a sound-based alarm to the user.

A temperature sensor T₃, to determine ventilator V₃ temperature, is connected to a temperature circuit 5009 which is also connected to light suppression switch 5001. The temperature circuit 5009 is also connected to the audible alarm suppression switch 5005 and the audible alarm 5006 to indicate a sound-based alarm to the user. The temperature circuit 5009 is used to determine if the ventilator V₃ is operating in a temperature range outside of the specified parameters.

An exhale pressure detect circuit 5010 is connected to at least one exhale event counter 5011 and an exhale event trigger 5012 per event counter. The exhale circuit 5010, event counter 5011 and event trigger 5012 is connected to the pressure sensor 1016 of the pneumatic subsystem N₃. The exhale event trigger 5012 is further connected to the light suppression switch 5001 and patient error LED indicator 5002 to denote an improper connection or patient distress to the user. The exhale circuit 5010, event counter 5011 and event trigger 5012 are also connected to the audible alarm suppression switch 5005 and the audible alarm 5006 to indicate a sound-based alarm to the user.

An inspiration pressure detect circuit 5013 is connected to at least one inspiration event counter 5014 and inspiration event trigger 5015 per event counter. When the air a_(c) pressure is too high or too low, pressure detect circuit 5013 generates an alarm response. The inspiration circuit 5013 is connected to the pressure sensor 1004 of the pneumatic subsystem N₃. The inspiration event trigger 5015 is further connected to the light suppression switch 5001 and patient error LED indicator 5002 to denote a improper connection or patient distress to the user. The inspiration pressure detect circuit 5013, inspiration event counter 5014 and inspiration event trigger 5015 are also connected to the audible alarm suppression switch 5005 and the audible alarm 5006 to indicate a sound-based alarm to the user. This inspiration pressure detect circuit 5013 can also cause the relay control switch 4002 d to immediately switch from operating the dual head compressor 1001 inhalation cycle to dual head compressor expiration cycle (off-state) through an alarm subsystem A₃ signal to safety cutoff circuit 4013, when a preset pressure threshold is exceeded, to prevent harm to patient H. 

1. A portable ventilator system comprising a pneumatic subsystem, a power subsystem, an alarm subsystem, a logic circuit connected to a patient breathing circuit wherein said logic circuit is further connected to a timing circuit wherein said logic circuit and said timing circuit comprise a control subsystem, wherein said control subsystem is constructed so as to connect to each of said subsystems and said breathing circuit; said pneumatic subsystem further comprising a dual-head compressor; said pneumatic subsystem, said power subsystem, said alarm subsystem and said control subsystem further constructed so as to be enclosed within and positioned on a housing having a recessed control panel; said housing connected to said patient breathing circuit.
 2. A portable ventilator system comprising: a hard shell device housing having an interior portion and an exterior surface; said interior portion including a power subsystem connected to a pneumatic subsystem, a control subsystem, and an alarm subsystem comprising a battery monitor LED, a device/system error LED, a patient error LED and an audible alarm wherein said battery monitor LED, said device/system error LED, and said patient error LED are positioned on a recessed control panel of said exterior surface; said pneumatic subsystem comprising a dual head compressor constructed so as to provide a patient with inhalation compressed air; said control subsystem comprising a timing circuit connected to a logic circuit, said logic circuit connected to a relay, said relay further connected to said dual head compressor so as to turn said dual head compressor on so as to deliver inhalation compressed air to a patient, and turn said dual head compressor off when said patient exhales; said power subsystem comprising a battery source connected to a current limit device, which in turn is connected to a power jack, so as to supply regulated power to said pneumatic, control and alarm subsystems, said electronic circuit and said power jack further constructed so as to connect to an external power source; said power subsystem further comprising a power switch connected to said battery, said power switch constructed so as to operate a buck/boost, said buck/boost constructed so as to accept a range of voltages from said power source and output a pre-set constant voltage; said power switch further connected to a voltage regulator, said voltage regulator constructed so as to supply lower voltages to said control and alarm subsystems; and said alarm subsystem further constructed so as to connect to said power subsystem and said battery monitor LED, said device/system error LED, said patient error LED and said audible alarm of said power subsystem so as to visually and audibly detect patient, device and battery problems in said ventilator system.
 3. A portable ventilator system as recited in claim 2 wherein said pneumatic subsystem further comprises a first input port constructed so as to allow ambient inhalation air to enter said ventilator; a first section of medical grade y-tubing constructed so as to divide said inhalation air into two flow paths; said dual head compressor consisting of first and second input ports and first and second output ports, said input ports constructed so as to receive said ambient inhalation air from said y-tubing, said dual head compressor constructed so as to compress said inhalation air, said first and second output ports further constructed as to dispel said compressed inhalation air from said dual head compressor; an air manifold constructed so as to receive said compressed inhalation air and dispel said compressed inhalation air to a first pressure sensor, said first pressure sensor constructed so as to detect pressure of said compressed inhalation air; said ventilator constructed so as to dispel said compressed air to a patient breathing circuit through a ventilator output port; and said ventilator further constructed so as to provide one-way air flow from said ventilator to said patient breathing circuit.
 4. A portable ventilator system as recited in claim 3 wherein a second input port is constructed so as to allow purified air to enter said ventilator; wherein said purified air is mixed with said ambient air so as to form said inhalation air.
 5. A portable ventilator system as recited in claim 4, wherein said patient breathing circuit comprises a respiratory tubing constructed so as to receive said compressed air, said respiratory tubing further constructed so as to provide a flow path to said compressed inhalation air from said ventilator output port to a breathing valve through a breathing valve input and subsequently to a breathing valve bi-directional port; said respiratory tubing and said breathing valve input constructed so as to only receive compressed air from said ventilator and deliver it to said patient; said patient breathing circuit further constructed so as to allow said compressed air to flow through a second respiratory tubing though an inline End-tidal CO₂ detector a third respiratory tubing and though a bi-directional port to said patient; said patient breathing circuit further constructed so as to close off said breathing valve input port and further constructed so as to allow exhaled air to exit said breathing circuit.
 6. A portable ventilator system as recited in claim 5, wherein said pneumatic subsystem further comprises a End-tidal CO₂ detector, said detector constructed so as to detect the presence of exhaled CO₂, said pneumatic subsystem further comprising a second pressure sensor, a manifold, a pressure port and tubing constructed so as to monitor both the patient inhalation and exhalation pressures.
 7. A portable ventilator system as recited in claim 6 wherein said relay of said control subsystem further comprises a relay switch bar constructed so as to be positioned at a first connector position when said patient is exhaling and a second connector position connecting said relay to said dual-head compressor, when said patient is inhaling; said timing circuit of said control subsystem is constructed so as to connect to a relay control through said logic circuit; said logic circuit further constructed so as to move said relay switch bar between said first connector position and said second connector position, based upon a breath-timing cycle generated by the timing circuit said logic circuit is further constructed so as to connect to a secondary breathing cycle switch and an alternative breathing cycle circuit, based upon selection of a secondary breathing-timing cycle by user dependent upon patient need, said timing circuit further constructed so as to connect to a capacitor, a first resistor and a second resistor, wherein said second resistor is connected to said power subsystem; said relay switch further constructed so as to connect to a first current sensor so as to verify the position of said switch bar at said first connector position and a second current sensor constructed so as to verify the position at said second connector position; said first current sensor further connected to said alarm subsystem so as to alert a user to alarm conditions should threshold current values not be met; said second current sensor further constructed so as to determine whether there is current to said dual-head compressor during inhalation-cycle; said second current sensor further connected to said alarm subsystem so as to alert said user to alarm conditions should threshold current values not be met; said second current sensor, said dual-head compressor and said alarm subsystem further connected to a safety cutoff circuit constructed so as to cut off power to the dual-head compressor when said ventilator is in an alarm state.
 8. A portable ventilator system as recited in claim 7 wherein said alarm subsystem further comprises a low voltage detect circuit connected to said battery and said power switch of said power subsystem so as to indicate when voltage is too low; said low voltage detect circuit is further connected to a light suppression switch and an audible alarm suppression switch; a patient/system/battery failure detect circuit is constructed so as to connect to said control subsystem, said light suppression switch, said audible alarm suppression switch and said audible alarm; a temperature sensor constructed so as to determine said ventilator temperature, is connected to a temperature circuit constructed so as to determine whether said ventilator is operating in a temperature range outside of the specified parameters, wherein said temperature circuit is connected to light suppression switch; said temperature circuit is further constructed so as to connect to said audible alarm suppression switch and said the audible alarm; an exhale pressure detect circuit is further constructed so as to connect to at least one exhale event counter, and an exhale event trigger constructed so as to connect to said second pressure sensor; said exhale event trigger constructed so as to further connect to said light suppression switch and said patient error LED indicator so as to denote an improper connection or patient distress; said exhale circuit, said event counter and said event trigger further constructed so as to connect to said audible alarm suppression switch and said audible alarm so as to indicate a sound-based alarm to user; an inspiration pressure detect circuit constructed so as to connect to at least one inspiration event counter and an inspiration event trigger so as to generate an alarm response when compressed air pressure is compromised; said inspiration circuit constructed so as to connect to said first pressure sensor of said pneumatic subsystem; said inspiration event trigger constructed so as to connect to said light suppression switch and said patient error LED indicator so as to denote a improper connection and patient distress to the user; said inspiration pressure detect circuit, said inspiration event counter, and said inspiration event trigger further constructed so as to connect to said audible alarm suppression switch and said audible alarm so as to indicate a sound-based alarm to user; said inspiration pressure detect circuit further constructed so as to cause said relay control switch to immediately switch from operating said dual head compressor inhalation cycle to said dual head compressor expiration cycle through a signal of said alarm subsystem to said safety cutoff circuit when a preset pressure threshold is exceeded.
 9. A method of operating a portable ventilator system comprising the steps of: (a) drawing inhalation air into a dual head compressor, (b) compressing said air in said dual head compressor and monitoring the pressure of said compressed air; (c) transferring said compressed inhalation air into an air manifold through a ventilator output port into a patient breathing circuit; (d) maintaining air flow in the direction of said patient breathing circuit; (e) transferring said compressed inhalation air to a patient through a second bi-directional port in said breathing valve; (f) providing inhalation air to a patient through said bi-directional port to a patient; (g) allowing exhalation air from said patient to enter bi-directional port; (h) transferring exhalation air through said exhale port and verifying the presence exhalation air using a second pressure sensor; and (i) removing exhalation air from said ventilator, through a patient exhale port.
 10. A method of operating a portable ventilator as recited in claim 9 and further comprising the step of: detecting presence of carbon dioxide in exhalation air using a End-tidal CO₂ detector.
 11. A method of operating a portable ventilator as recited in claim 10 and further comprising the steps of (a) obtaining said on and off cycles using a timing circuit; (b) controlling on and off cycles for said dual head compressor using a relay switch; (c) obtaining inhalation and exhalation cycles for the patient using said portable ventilator, said inhalation and exhalation cycles corresponding to said on and off cycles of said dual head compressor; (d) providing visual and audible alarms corresponding to patient related problems; (e) providing visual and audible alarms corresponding to ventilator system problems; and (f) providing visual and audible alarms corresponding to power problems. 